Convolutional neural networks for long-time dissipative quantum dynamics
Abstract
Exact numerical simulations of dynamics of open quantum systems often require immense computational resources. We demonstrate that a deep artificial neural network comprised of convolutional layers is a powerful tool for predicting long-time dynamics of an open quantum system provided the preceding short-time dynamics of the system is known. The neural network model developed in this work simulates long-time dynamics efficiently and very accurately across different dynamical regimes from weakly damped coherent motion to incoherent relaxation. The model was trained on a data set relevant to photosynthetic excitation energy transfer and can be deployed to study long-lasting quantum coherence phenomena observed in light-harvesting complexes. Furthermore, our model performs well for the initial conditions different than those used in the training. Our approach considerably reduces the required computational resources for long-time simulations and holds promise for becoming a valuable tool in the study of open quantum systems.
Cite
@article{arxiv.2012.11009,
title = {Convolutional neural networks for long-time dissipative quantum dynamics},
author = {Luis E. Herrera Rodriguez and Alexei A. Kananenka},
journal= {arXiv preprint arXiv:2012.11009},
year = {2020}
}
Comments
9 pages, 3 figures